Summary
Neither pinealectomy nor administration of melatoninvia silastic capsules had any effect on free-running circadian rhythms of locomotor activity in Japanese quail (Coturnix coturnix japonica). The quail, like the chicken, therefore differs from sparrows and starlings in which pinealectomy dramatically disrupts free-running rhythms. Nevertheless, it seems unlikely that there are fundamental differences in circadian organisation within the Class Aves. The effects of lesions within the supraoptic region (SOR) of the hypothalamus were similar to those which follow the ablation of the suprachiasmatic nuclei (SCN) in sparrows, rats and hamsters, causing the breakdown of free-running rhythms of locomotor activity, but not necessarily an arrhythmic state. The SOR and SCN appear then to have homologous functions in birds and mammals. Differences in circadian organisation, such as the degree of influence of the pineal gland and the particular photoreceptors used for entrainment, may therefore be modifications peripheral to the fundamental components of the circadian clock.
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Abbreviations
- POR :
-
preoptic area
- SOR :
-
supraoptic region
- SCN :
-
suprachiasmatic nuclei
References
Baylé J-D, Ramade F, Oliver J (1974) Stereotaxis topography of the brain of the quail (Coturnixcoturnix japonica). J Physiol (Paris) 68:219–241
Benoit J (1970) Étude de l'action des radiations visibles sur la gonadostimulation et de leur pénétration intracranienne chez les oiseaux et les mammifères. In: Benoit J, Assenmacher I (eds) La photorégulation de la reproduction chez les oiseaux et les mammifères. CNRS, Paris, pp 121–146
Binkley S (1974) Pineal and melatonin: Circadian rhythms and body temperature of sparrows. In: Sheving LE, Halberg F, Pauly JE (eds) Chronobiology. Shoin, Tokyo, pp 582–585
Binkley S, Kluth E, Menaker M (1971) Pineal function in sparrows: Circadian rhythms and body temperature. Science 174:311–314
Brown-Grant K, Raisman G (1977) Abnormalities in reproductive function associated with the destruction of the suprachiasmatic nuclei in female rats. Proc R Soc Lond [Biol] 198:279–296
Daan S, Pittendrigh CS (1976) A functional analysis of Circadian pacemakers in nocturnal rodents. II. The variability of phase response curves. J Comp Physiol 106:253–266
Davies DT (1980) The neuroendocrine control of gonadotrophin release in the Japanese quail III. The role of the tuberal and anterior hypothalamus in the control of ovarian development and ovulation. Proc R Soc Lond [Biol] 206:421–437
Davies DT, Follett BK (1975a) The neuroendocrine control of gonadotrophin release in the Japanese quail. I. The role of the tuberal hypothalamus. Proc R Soc Lond [Biol] 191:285–301
Davies DT, Follett BK (1975b) The neuroendocrine control of gonadotrophin release in the Japanese quail. II. The role of the anterior hypothalamus. Proc R Soc Lond [Biol] 191:303–315
Ebihara S, Kawamura H (1980) Central mechanism of circadian rhythms in birds. In: Tanabe Y, Tanaka K, Ookawa T (eds) Biological rhythms in birds. Neural and endocrine aspects. Springer, Berlin Heidelberg New York, pp 71–78
Finkelstein JS, Baum FR, Campbell CS (1978) Entrainment of the female hamster to reversed photoperiod: Role of the pineal. Physiol Behav 21:105–111
Fleming DG (1957) A constant current apparatus for the production of electrolytic lesions. Electroencephalogr Clin Neurophysiol 9:551–554
Follett BK (1973) Circadian rhythms and photoperiodic time measurement in birds. J Reprod Fertil Suppl 19:5–18
Follett BK, Maung SL (1978) Rate of testicular maturation, in relation to gonadotrophin and testosterone levels, in quail exposed to various artificial photoperiods and to natural daylengths. J Endocrinol 78:267–280
Follett BK, Robinson JE, Simpson SM, Harlow CR (1981) Photo- periodic time measurement and gonadotrophin secretion in quail. In: Follett BK, Follett DE (eds) Biological clocks in seasonal reproductive cycles. Wright, Bristol, pp 185–197
Gaston S (1971) The influence of the pineal organ on the circadian activity rhythms in birds. In: Menaker M (ed) Biochronometry. National Academy of Sciences, Washington, DC, pp 541–549
Gaston S, Menaker M (1968) Pineal function: The biological clock in the sparrow? Science 160:1125–1127
Gwinner E (1978) Effects of pinealectomy on circadian locomotor activity rhythms in European starlingsSturnus vulgaris. J Comp Physiol 126:123–129
Gwinner E, Benzinger I (1978) Synchronisation of a circadian rhythm in pinealectomized European starlings by daily injections of melatonin. J Comp Physiol 127:209–213
Hendel RC, Turek FW (1978) Suppression of locomotor activity in sparrows by treatment with melatonin. Physiol Behav 21:275–278
Herbert J (1981) The pineal gland and the photoperiodic control of the ferret's reproductive cycle. In: Follett BK, Follett DE (eds) Biological clocks in seasonal reproductive cycles. Wright, Bristol, pp 261–275
Hishikawa Y, Cramer H, Kuhlo W (1969) Natural and melatonin- induced sleep in young chickens — a behavioural and electrographic study. Exp Brain Res 7:84–94
Hoffmann K (1981) The role of the pineal gland in the photoperiodic control of seasonal cycles in hamsters. In: Follett BK, Follett DE (eds) Biological clocks in seasonal reproductive cycles. Wright, Bristol, pp 237–249
Homma K, Ohta M, Sakakibara Y (1979) Photoinducible phase of the Japanese quail detected by direct stimulation of the brain. In: Suda M, Hayaishi O, Nakagawa H (eds) Biological rhythms and their central mechanism. Elsevier/North Holland, Amsterdam, pp 85–94
Konishi T (1980) Circadian rhythm of ovipositional time in Japanese quail. In: Tanabe Y, Tanaka K, Ookawa T (eds) Biological rhythms in birds. Neural and endocrine aspects. Springer, Berlin Heidelberg New York, pp 79–90
MacBride SE (1973) Pineal biochemical rhythms of the chicken (Gallus domesticus): light cycle and locomotor activity correlates. PhD thesis, University of Pittsburgh
McMillan J (1972) Pinealectomy abolishes the circadian rhythm of migratory restlessness. J Comp Physiol 79:105–112
Menaker M, Zimmerman N (1976) Role of the pineal in the circadian system of birds. Am Zool 16:45–55
Menaker M, Hudson DJ, Takahashi J (1981) Neural and endocrine components of circadian clocks in birds. In: Follett BK, Follett DE (eds) Biological clocks in seasonal reproductive cycles. Wright, Bristol, pp 171–183
Moore RY, Eichler VB (1972) Loss of a circadian adrenal corticosterone rhythm following suprachiasmatic lesions in the rat. Brain Res 42:201–206
Oliver J, Baylé J-D (1973) Photically evoked potentials in the gonadotropic areas of the quail hypothalamus. Brain Res 64:103–121
Oliver J, Baylé J-D (1976) The involvement of the preoptic-suprachiasmatic region in the photosexual reflex in quail: Effects of selective lesions and photic stimulation. J Physiol (Paris) 72:627–637
Pittendrigh CS (1972) Circadian surfaces and the diversity of possible roles of circadian organisation in photoperiodic induction. Proc Natl Acad Sci USA 69:2734–2737
Pittendrigh CS (1981) Circadian organisation and the photoperiodic phenomena. In: Follett BK, Follett DE (eds) Biological clocks in seasonal reproductive cycles. Wright, Bristol, pp 1–35
Quay WB (1968) Individuation and lack of pineal effect in the rats' circadian locomotor rhythm. Physiol Behav 3:109–118
Quay WB (1970a) Precocious entrainment and associated characteristics of activity patterns following pinealectomy and reversal of photoperiod. Physiol Behav 5:1281–1290
Quay WB (1970b) Physiological significance of the pineal during adaptation to shifts in photoperiod. Physiol Behav 5:353–360
Rusak B (1977) The role of the suprachiasmatic nuclei in the generation of circadian rhythms in the golden hamster,Mesocricetus auratus. J Comp Physiol 118:165–172
Rusak B (1979) Neural mechanisms for entrainment and generation of mammalian circadian rhythms. Fed Proc 38:2589–2595
Rusak B, Morin LP (1976) Testicular responses to photoperiod are blocked by lesions of the suprachiasmatic nuclei in golden hamsters. Biol Reprod 15:366–374
Rusak B, Zucker I (1979) Neural regulation of circadian rhythms. Physiol Rev 59:449–526
Rutledge JT, Angle MJ (1977) Persistence of circadian activity rhythms in pinealectomised European starlings (Sturnus vulgaris). J Exp Zool 202:333–337
Sharp PJ, Follett BK (1969) The effect of hypothalamic lesions on gonadotrophin release in Japanese quail (Coturnix coturnix japonica). Neuroendocrinol 5:205–218
Simpson SM, Follett BK (1980) The role of the pineal and anterior hypothalamus in regulating the circadian rhythm of locomotor activity in Japanese quail. In: Nöhring R (ed) XVII Congressus Internationalis Ornithologici. Deutsche Ornithologen-Gesellschaft, Berlin, pp 435–438
Simpson SM, Follett BK (1981a) Formal properties of the circadian rhythm of locomotor activity in Japanese quail. J Comp Physiol (in press)
Simpson SM, Follett BK (1981b) Formal properties of the circadian system underlying photoperiodic time measurement in Japanese quail. J Comp Physiol (in press)
Stephan FK, Zucker I (1972) Circadian rhythms in drinking behaviour and locomotor activity of rats are eliminated by hypothalamic lesions. Proc Natl Acad Sci USA 69:1583–1586
Stetson MH (1972a) Hypothalamic regulation of gonadotrophin release in female Japanese quail. Z Zellforsch 130:411–428
Stetson MH (1972b) Hypothalamic regulation of testicular function in Japanese quail. Z Zellforsch 130:389–410
Stetson MH, Watson-Whitmyre M (1976) Nucleus suprachiasmaticus: The biological clock in the hamster? Science 191:197–199
Takahashi JS, Menaker M (1979a) Brain mechanisms in avian circadian systems. In: Suda M, Hayaishi O, Hachiro N (eds) Biological rhythms and their central mechanism. Elsevier/North Holland, Amsterdam, pp 95–109
Takahashi JS, Menaker M (1979b) Physiology of avian circadian pacemakers. Fed Proc 38 (12):2583–2588
Turek FW, McMillan JP, Menaker M (1976) Melatonin: Effects on the circadian locomotor rhythm of sparrows. Science 194:1441–1443
Underwood H (1977) Circadian organisation in lizards: The role of the pineal organ. Science 195:587–589
Underwood H (1979) Melatonin affects circadian rhythmicity in lizards. J Comp Physiol 130:317–323
Winer BJ (1971) Statistical principles in experimental design. McGraw-Hill, Igakushoin Tokyo
Yokoyama K, Oksche A, Darden TR, Farner DS (1978) The sites of encephalic photoreception in photoperiodic induction of the growth of the testes in the white-crowned sparrow,Zonotrichia leucophrys gambellii. Cell Tissue Res 189:441–467
Zimmerman N, Menaker M (1975) Neural connections of sparrow pineal: role in circadian control of activity. Science 190:477–479
Zimmerman N, Menaker M (1979) The pineal: a pacemaker within the circadian system of the house sparrow. Proc Natl Acad Sci USA 76:999–1003
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Simpson, S.M., Follett, B.K. Pineal and hypothalamic pacemakers: Their role in regulating circadian rhythmicity in Japanese quail. J. Comp. Physiol. 144, 381–389 (1981). https://doi.org/10.1007/BF00612570
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DOI: https://doi.org/10.1007/BF00612570